Organohydrogel based on cellulose-stabilized emulsion for electromagnetic shielding, flame retardant, and strain sensing

Abstract

In the past, electromagnetic interference (EMI) shielding materials have achieved great breakthroughs, however, they still suffer from high reflectivity and poor environmental stability, resulting in detrimental secondary pollution and weak adaptability. Herein, an organohydrogel-based EMI shielding material was prepared through cellulose nanofibril-based Pickering emulsion, composed of an MXene network for electron conduction, encapsulated paraffin wax microspheres with MXene-Fe3O4 shells for multiple scattering of the incident wave, and MXene-CNF-Fe3O4-polyacrylamide hybrid interfaces for dielectric polarization. The EMI shielding performance of our organohydrogel shows an absorption-dominated feature. It can effectively shield 99.625 % electromagnetic wave, satisfying the requirement of commercial EMI shielding materials. Moreover, the organohydrogel possesses excellent flame retardancy properties and long-time environment properties to improve safety and reliability; and it also demonstrates sensitive deformation responses as an on-skin sensor. Therefore, our organohydrogel can simultaneously detect human motion and protect human from EMI radiation and accidental burn.